Puckering Seal for Reduced Paravalvular Leakage

ABSTRACT

A heart valve assembly includes a heart valve, a self-expandable and collapsible stent, and a sealing member. The stent includes an inflow end and an outflow end and is configured to support the heart valve internally. The sealing member is connected to and extends circumferentially around the stent. The sealing member includes a plurality of radially outward extending protrusions comprising a fold of material of the sealing member.

CROSS-REFERENCES TO RELATED APPLICATIONS

The present application claims the benefit of the filing date of U.S.Provisional Patent Application No. 61/839,760, filed Jun. 26, 2013, thedisclosure of which is hereby incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to replacement heart valves, and moreparticularly relates to collapsible heart valves and associated sealingdevices and methods.

BACKGROUND OF THE INVENTION

Prosthetic heart valves may be formed from biological materials such asharvested bovine valves or pericardial tissue. These valves aretypically fitted within a stent, which may be inserted into the heart atthe annulus of the compromised native valve to replace the native valve.To perform an insertion procedure using a minimally invasivetranscatheter technique, it may be necessary to compress the stent to areduced diameter for loading into a delivery device.

Paravalvular (or perivalvular) leak (PVL) is a relatively rarecomplication related to the replacement of native heart valves. PVLdescribes a condition of blood flowing between the implanted valvestructure and the cardiac tissue rather than through the implanted valvestructure as desired. While most PVLs are hemodynamicallynon-significant, significant leaks may be problematic and requirefurther intervention.

SUMMARY OF THE INVENTION

One aspect of the present disclosure relates to a heart valve assemblythat includes a heart valve, a self-expandable and collapsible stent,and a sealing member. The stent includes an inflow end and an outflowend and is configured to support the heart valve internally. The sealingmember is connected to and extends circumferentially around the stent.The sealing member includes a plurality of radially outward extendingprotrusions comprising a fold of material of the sealing member.

Another aspect of the present disclosure relates to a sealing member foruse with a valve assembly. The sealing member includes a base configuredfor attachment to a self-expandable and collapsible stent. A pluralityof protrusions are formed in a radially outward facing surface of thebase and configured to provide a sealed interface between the valveassembly and an annulus at an implantation site.

Another aspect of the present disclosure relates to a method ofmanufacturing a valve assembly. The method includes providing a stent, avalve, and a sealing member. The stent has a self-expandable andcollapsible construction. The sealing member includes a plurality ofprotrusions. The method further includes mounting the valve within thestent, and mounting the sealing member to the stent with the pluralityof protrusions extending radially outward.

The foregoing and other features, utilities, and advantages of theinvention will be apparent from the following detailed description ofthe invention with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a heart valve assembly in accordancewith the present disclosure.

FIG. 2 is an exploded perspective view of the heart valve assembly ofFIG. 1.

FIG. 3 is a perspective view of a sealing member of the heart valveassembly of FIG. 1.

FIG. 4 is a side view of the sealing member of FIG. 3.

FIG. 5 is a cross-sectional view of the sealing member of FIG. 3 takenalong cross-section indicators 5-5.

FIG. 6 is a cross-sectional view of the heart valve assembly of FIG. 1taken along cross-section indicators 6-6 with a first suture connectionarrangement.

FIG. 7 is a cross-sectional view of the heart valve assembly of FIG. 1taken along cross-section indicators 7-7 with an alternative secondsuture connection arrangement.

FIG. 8 is a side view of another heart valve assembly in accordance withthe present disclosure.

FIG. 9 is a cross-sectional view of a sealing member of the heart valveassembly of FIG. 8.

FIG. 10 is a side view of the heart valve assembly of FIG. 8 with thesealing member positioned at a different axial position.

FIG. 11 is a side view of another heart valve assembly with a sealingmember arranged at an angle.

FIG. 12 is a side view of another heart valve assembly with a sealingmember having two rows of sealing protrusions.

FIG. 13 is a side view of another heart valve assembly with a sealingmember protruding through cells of a stent.

FIG. 14 is a cross-sectional view of the heart valve assembly of FIG. 13taken along cross-section indicators 14-14.

FIG. 15 is a side view of the heart valve assembly of FIG. 1 with adelivery system prior to deployment.

FIG. 16 is a cross-sectional view of the heart valve assembly anddelivery apparatus of FIG. 15 taken along cross-section indicators16-16.

FIG. 17 shows the heart valve assembly of FIGS. 15 and 16 partiallydeployed.

FIG. 18 shows the heart valve assembly of FIGS. 15 and 16 fully deployedand detached from the delivery apparatus.

FIG. 19 shows the heart valve assembly of FIG. 1 partially deployed at anative annulus of a heart.

FIG. 20 shows the heart valve assembly of FIG. 1 fully deployed at anative annulus of a heart.

DETAILED DESCRIPTION

The present disclosure relates to implantable heart valve assemblieshaving features that address paravalvular leak (PVL). PVL involves theflow of blood around the outside of the implantable heart valve assemblybetween the heart valve assembly and a native annulus within which theheart valve assembly is positioned. The native annulus may include theannulus of a native heart valve, which is being replaced by theimplantable heart valve assembly. PVL typically occurs when the heartvalve assembly is initially placed at the native annulus andinsufficient time has elapsed for tissue in-growth through the stent ofthe heart valve assembly, which usually mitigates PVL. One object of thepresent disclosure is to create a seal between an exterior of the heartvalve assembly and the native valve annulus upon implantation.

One aspect of the present disclosure relates to systems and methods forproviding a sealing interface between the heart valve assembly and thenative annulus at the implantation site. The sealing interface mayinclude a sealing member. The sealing member may be separate from avalve member carried by the stent. The sealing member may be positionedaround an outer perimeter surface of the stent. Alternatively, thesealing member may be positioned along an internal surface of the stent.The sealing member may include a plurality of protrusions that extendradially outward into contact with the native annulus. The protrusionsmay be referred to as puckers, tissue puckers, or folds, and may beformed in a radially outward facing surface of the sealing member. Theprotrusions may be arranged in a pattern. The protrusions may create acontinuous sealing line or sealing interface with the native annulus tolimit backflow of blood between the native annulus and an outer surfaceof the heart valve assembly. In an arrangement in which the sealingmember is positioned along an internal surface of the stent, theprotrusions may extend through cells or openings in the stent and intocontact with the native annulus.

The need for a sealing member and associated sealing protrusions mayarise from the use of a self-expanding stent of a self-expanding heartvalve assembly. Self-expanding stents, as opposed to balloon inflatedstents, may produce limited radially outward directed force against thenative annulus. This limited radial force may create challenges inmaintaining a seal between the stent and the native annulus without theuse of a sealing member and/or associated sealing protrusions of thesealing member. A self-expanding stent may include regions that do notclosely conform to the native annulus geometry due to unique shapes ofthe native valve. However, using a self-expanding stent may permit atleast partially re-sheathing of the heart valve assembly to repositionthe heart valve assembly relative to the native annulus duringdeployment.

The protrusions of the sealing member may fill gaps between the heartvalve assembly and the native annulus which may otherwise provide flowpaths that create PVL. The sealing protrusions may be compressible inother areas where the self-expanding stent has a close fit with thenative annulus geometry.

The sealing member may be secured to the stent in a way that permitsboth deployment and re-sheathing of the heart valve assembly relative toa carrier tube used to deliver the heart valve assembly to theimplantation site. For example, the sealing member may be connected tothe stent at a plurality of locations along a length of the stent andaround an outer peripheral surface of the stent to permit expansion andcontraction of the stent without pinching or damaging the sealingmember. In one example, the sealing member is connected to the stentwith stitching at intersections between support struts of the stent(e.g., at an apex of one of the cells). The stitching may permit somerelative movement between the stent and the sealing member.

Referring now to FIGS. 1-2, an example heart valve assembly 10 is shownincluding stent 12, sealing member 14, and valve 16. Sealing member 14is positioned on an exterior of stent 12 and extends around an outerperiphery of stent 12. Valve 16 is positioned internally within stent12. Heart valve assembly 10 may be positioned at an implantation siteand may be used as a replacement valve for a native valve of the heart.Stent 12 may be a self-expandable and collapsible device and may bereferred to as a self-expandable and collapsible stent.

Stent 12 may include inflow and outflow end portions 20, 22, interior24, plurality of frame members 26 (also referred to as struts 26), andplurality of cells 28. Stent 12 may have several sections along itslength including annular section 30, sinus section 32, and aorticsection 34 (see FIG. 2). Aortic section 34 may be flared to a greaterouter diameter than annular and sinus sections 30, 32. Annular, sinusand aortic sections 30, 32, 34 may provide different amounts of radiallyoutward directed force at the implantation site, which may affect, forexample, the sealing function of sealing member 14.

Sealing member 14 may provide an interface between a native annulus andstent 12 and/or valve 16. Sealing member 14 may provide an improved sealbetween the native annulus and heart valve assembly 10 that reduces PVL.

Valve 16 includes leaflets 35 and cuff 36. Cuff 36 typically extendsdistally to inflow end portion 20 of stent 12. Leaflets 35 may beconnected to stent 12 with connecting members 37 (see FIG. 1).Connecting members 37 are typically positioned along sinus section 32 ofstent 12. Cuff 36 may be connected to stent 12 at a plurality oflocations along the length L and around a circumference of stent 12using, for example, stitching 38 (see FIG. 1).

Sealing member 14 may be generally annular and include base 39 andplurality of protrusions 40, as shown in FIGS. 3-5. Each protrusion 40includes center 42, perimeter 44, and stitching 46. Sealing member 14 ispositioned extending around an outer circumferential surface of stent 12when heart valve assembly 10 is assembled (see FIG. 1). Base 39 may havean inner surface that faces radially inward toward stent 12. Protrusions40 extend radially outward away from base 39 and stent 12.

Each center 42 may extend centrally relative to perimeter 44. Center 42may extend in a direction parallel with a longitudinal axis A of sealingmember 14 (see FIG. 3). Perimeter 44 is typically in contact with stent12 along base 39. Center 42 protrudes radially outward away from base39. Protrusions 40 may have a diamond shape or half-diamond shape.Alternatively, each protrusion 40 may include or be referred to as ahemispherical, triangular, or conical shape.

Centers 42 define radially outward-most points along an exterior surfaceof sealing member 14. Centers 42 may include peak points relative toeach protrusion 40 in a radially outward direction. Centers 42 mayextend radially outward from perimeter 44 along base 39 a distance C(see FIGS. 4 and 5) in the range of about 0 mm to about 4 mm, and moreparticularly in the range of about 0 mm to about 1.5 mm. Distance C maybe applicable to any of the protrusion embodiments disclosed herein.

Protrusions 40 may be referred to as puckers, puckering, or folds, whichare formed in sealing member 14. Protrusions 40 may be formed bypinching, folding, gathering, or puckering portions of sealing member14. The resulting radially outward protruding shape of protrusion 40 maybe maintained using, for example, stitching 46. Stitching 46 is securedto material of protrusion 40 and may extend along center 42 and/orperimeter 44. Stitching 46 may define at least in part a shape and sizeof protrusion 40. For example, a location and shape of perimeter 44 maybe determined by location and type of stitching 46 used.

Each center 42 may be deformable and compressible to conform to unevensurfaces of the native annulus to enhance a sealed interface betweenheart valve assembly 10 and the native annulus. The materials of sealingmember 14, particularly those materials included in center 42, mayprovide deformable properties to center 42. For example, using aresilient, elastic material may permit a change of shape for protrusion40 and particularly center 42. A shape and size of center 42 may providedeformability and compressibility of center 42 when pressed radiallyoutward against the native annulus by stent 12.

Stitching 46 may assist in holding center 42 in a position protrudingradially outward. Stitching 46 may be secured to protrusion 40 in a waythat creates tension in center 42 to help maintain the pinched, puckeredand/or folded configuration of protrusions 40. Stitching 46 may include,for example, a ladder stitch or a whip stitch.

Each perimeter 44 may provide a continuous sealing interface betweenheart valve assembly 10 and the native annulus that limits backflow ofblood between the native annulus and heart valve assembly 10. Eachcenter 42 and perimeter 44 individually or in combination with eachother and/or base 39 may provide a cupping function against bloodbackflow, wherein center 42 and perimeter 44 of each protrusion 40create a liquid-tight cupping or sealing interface between heart valveassembly 10 and the native annulus. Perimeter 44 may follow framemembers 26. Perimeter 44 may be captured between frame members 26 andthe native annulus as stent 12 applies a radially outward directed forceto sealing member 14. Any portion of sealing member 14 captured betweenone of frame members 26 and the native annulus may provide a sealingpoint between heart valve assembly 10 and sealing member 14.

In other arrangements, perimeter 44 may be oriented on sealing member 14at a location spaced away from frame members 26. Perimeter 44 may definea boundary between protrusions 40 and base 39 of sealing member 14.Protrusions 40 may begin to extend radially outward from the remainingportions of sealing member 14 at the boundary provided by perimeter 44.

Protrusions 40 may be positioned in series around an outer perimetersurface of sealing member 14 as shown in the side and cross-sectionalviews of sealing member 14 in FIGS. 4 and 5. Protrusions 40 may bepositioned adjacent to each other and may be arranged side-by-side andin contact with each other. Protrusions 40 may be aligned linearlyaround an outer circumferential surface of base 39 of sealing member 14.Protrusions 40 may be arranged in a pattern of repeating shapes.Protrusions 40 may have the same size. Alternatively, protrusions 40 mayhave different shapes and sizes around a perimeter of sealing member 14.

Sealing member 14 has a length L₁ as shown in FIGS. 4 and 5. Length L₁may be less than a length of any one of annular, sinus and aorticsections 30, 32, 34 of stent 12. At its greatest length, length L₁ isless than length L of stent 12 (see FIG. 2). Length L₁ is typicallygreat enough to provide overlapping with at least a portion of valve 16when sealing member 14 is positioned at any location along length L ofstent 12.

The portion of sealing member 14 that overlaps with valve 16 may beconnected to valve 16 either directly or indirectly. Sealing member 14and valve 16 may be directly connected together using, for example,fasteners, stitching, or a bonding agent.

Protrusions 40 may coincide with the shape and size of cells 28, or aportion of cells 28 of stent 12 (see FIGS. 1 and 2). Protrusions 40,including perimeters 44 of protrusions 40, may have a shape thatsubstantially matches the horseshoe-shaped, half cells 28 (also referredto as half diamond shaped portions) along inflow end portion 20 of stent12. In at least some arrangements, protrusions 40 are axially spacedfrom inflow end portion 20 such that sealing member 14 may have a shapethat matches an entire cell 28 of stent 12. Sealing member 14 may bearranged on stent 12 at a location to provide alignment with the nativeannulus at the implantation site.

Sealing member 14 may be connected to stent 12 using any suitableattachment method. For example, sealing member 14 of heart valveassembly 10 may be connected to stent 12 using stitching 48, as shown inFIG. 6. Stitching 48 may extend around or adjacent to portions of framemembers 26 and extend through base 39 of sealing member 14. FIG. 6 showsstitching 48 extending only through sealing member 14 and wrappingaround portions of frame members 26. Separate stitching 38 extendsthrough cuff 36 of valve 16 and wraps around portions of frame members26 to secure valve 16 to stent 12. Stitching 38 and attachment stitching48 may be positioned axially adjacent to each other. The stitchingarrangement of FIG. 6 may be helpful when connecting sealing member 14to stent 12 in a separate assembly step from connecting valve 16 tostent 12. For example, valve 16 may be mounted to stent 12 withstitching 38 followed by mounting sealing member 14 to stent 12 withstitching 48. Stitching 48 may be positioned at any location along framemembers 26 such as at intersection points of frame members 26.

FIG. 7 shows stitching 48 extending through cuff 36 of valve 16, aroundportions of frame members 26, and through base 39 of sealing member 14.Stitching 48 may extend along a portion of two separate frame members26, as shown in FIG. 7. Stitching 48 may extend through each of sealingmember 14 and valve 16 at two separate locations. The arrangement ofFIG. 7 includes a single stitching 48 connecting sealing member 14 andvalve 16 together and connecting sealing member 14 and valve 16 to stent12.

As shown in FIG. 7, a gap G exists between center 42 of protrusion 40and valve 16. Gap G provides a space into 14 which center 42 may deformradially inwardly when sealing member is pressed against the geometry ofthe native annulus. Center 42 may elastically deform into gap G andreturn to the rest position shown in FIG. 7 after being removed fromcontact with the native annulus. Stitching 48 holds base 39 of sealingmember 14 secured to stent 12 while center 42 deforms into gap G.

FIG. 8 shows heart valve assembly 100 having stent 112, sealing member114, and valve 116. Stent 112 includes inflow and outflow end portions120, 122, interior 124, frame members 126, cells 128, and annular, sinusand aortic sections 130, 132, 134. Valve 116 includes leaflets 135 andcuff 136. Leaflets 135 of valve 116 may be connected to stent 112 withconnecting members 137. Connecting members 137 are typically positionedalong sinus section 132 of stent 112. Cuff 136 of valve 116 may beconnected to stent 112 with stitching 138.

Sealing member 114 includes base 139 and plurality of protrusions 140.Each protrusion 140 includes center 142, perimeter 144, and stitching146 (see FIG. 9). Each protrusion 140 has a generally diamond-shapedperimeter 144. Each protrusion 140 may have a shape that generallymatches a shape of cell 128 of stent 112 aligned with protrusion 140, asshown in FIG. 8. Perimeter 144 of each protrusion 140 may track alongframe members 126 of stent 112 that are covered by sealing member 114.Sealing member 114 may be connected to frame members 126 along perimeter144 of at least some of protrusions 140 using, for example, stitching148. Center 142 may extend longitudinally between axially spaced apartapexes of cells 128.

Protrusions 140 may have a contoured, generally dome-shapedconstruction, as shown in the cross-sectional view of FIG. 9. Stitching146 may extend along center 142 and apply tension in material of sealingmember 14 that holds center 142 extending radially outward relative toperimeter 144 and/or base 139. Stitching 146 may include, for example, aladder stitch or a whip stitch.

Sealing member 114 typically overlaps at least a portion of valve 116,as shown in FIG. 8. Sealing member 114 may be positioned directlyadjacent to one of the ends of valve 116. Typically, sealing member 114is positioned distal (e.g., toward the heart and away from the operator)of leaflets 135 of valve 116 and overlapping cuff 136 to provideimproved sealing between the native annulus and valve 116.

Sealing member 114 may be connected to stent 112 using, for example,stitching, adhesives, or fasteners. In one example, attachment stitching148 may be used to connect sealing member 114 to frame members 126 ofstent 112. In at least some examples, attachment stitching 148 may bepositioned at the intersection of frame members 126. Attachmentstitching 148 may be able to slide along frame members 126 to permitsome relative movement between sealing member 114 and stent 112 duringexpansion and collapsing of stent 112. Cuff 136 of valve 116 may also beconnected to stent 112 using attachment stitching 148. Attachmentstitching 148 may be used to connect sealing member 114 to stent 112,valve 116 to stent 112, and sealing member 114 to valve 116.

Sealing member 114 has a length L₂, as shown in FIG. 9. Length L₂ may besubstantially the same length as a length of cells 28 along that portionof stent 112 overlapped by sealing member 114. Length L₂ may be lessthan a length of any one of annular, sinus and aortic sections 130, 132,134 of stent 112. Length L₂ typically is less than half of length L ofstent 112 (see FIG. 8).

Sealing member 114 may be positioned at other axial positions alonglength L of stent 112, such as the position shown in FIG. 10. FIG. 10shows an embodiment similar to FIG. 8, the details of which will not berepeated for the sake of brevity. FIG. 10 shows sealing member 114positioned primarily within sinus section 132 of stent 112 rather thanoverlapping annular and sinus sections 130, 132 as in the arrangement ofFIG. 8. In other embodiments, sealing member 114 may at least partiallyoverlap multiple sections 130, 132, 134, such as partially overlappingaortic section 134 in addition to annular section 130 and/or sinussection 132.

FIG. 11 shows heart valve assembly 200 having stent 212, sealing member214, and valve 216. Stent 212 includes inflow and outflow end portions220, 222, plurality of frame members 226 that define plurality of cells228, and annular, sinus and aortic sections 230, 232 and 234. Valve 216may be connected to stent 212 with connecting members 237 and stitching238. Connecting members 237 are typically positioned along sinus section232 of stent 212.

Central axis A of sealing member 214 may be arranged at angle α relativeto longitudinal axis B of stent 212 rather than being coaxial withlongitudinal axis B (as compared to the coaxial arrangements of FIGS.1-10). Angle α is typically in the range of about 0° to about 45°, andmore particularly in the range of about 10° to about 30°.

Sealing member 214 may span or extend across multiple sections of stent212, such as annular section 230 and sinus section 232, or sinus section232 and aortic section 234. Alternatively, sealing member 214 may bepositioned within only one of annular, sinus and aortic sections 230,232, 234.

Sealing member 214 includes base 239 and a plurality of protrusions 240.Protrusions 240 each include center 242, perimeter 244, and stitching246. At least some of protrusions 240 may overlap portions of multiplecells 228 of stent 212.

The angled arrangement of sealing member 214 may address challengesassociated with off-axis arrangements of the native annulus that resultfrom, for example, off-axis arrangement of the aorta relative to theheart. For example, if the aorta is arranged at an angle α from acentral axis of the annulus, sealing member 214 may also be positionedat an angle α relative to stent 212 to provide better alignment ofsealing member 214 with the native annulus.

Sealing member 214 may be connected to stent 212 using, for example,attachment stitching 248. In at least some examples, attachmentstitching 248 may be connected to stent 212 at the intersection of framemembers 226. Attachment stitching 248 may be able to slide along atleast some of frame members 226 to permit some relative movement betweensealing member 214 and stent 212 during expansion and collapsing ofstent 212 while still maintaining the angled orientation of sealingmember 214.

FIG. 12 shows heart valve assembly 300 having stent 312, sealing member314, and valve 316. Stent 312 includes inflow and outflow end portions320, 322 and plurality of frame members 326 that define a plurality ofcells 328. Valve 316 includes leaflets 335 and cuff 336. Leaflets 335may be connected to stent 312 with connecting members 337. Cuff 336 ofvalve 316 may be connected to stent 312 with stitching 338.

Sealing member 314 includes base 339 and plurality of protrusions 340 a,340 b. Each of protrusions 340 a, 340 b includes center 342, perimeter344, and stitching 346. Protrusions 340 a, 340 b may be arranged infirst and second rows 347 a, 347 b, respectively. First and second rows347 a, 347 b are arranged axially in series and directly adjacent toeach other along a length of sealing member 314. First row 347 a may bepositioned adjacent to or closest to inflow end portion 320.

Protrusions 340 a in first row 347 a are circumferentially offsetrelative to protrusions 340 b in second row 347 b. Protrusions 340 a maybe arranged out of axial alignment with protrusions 340 b in an axialdirection. Protrusions 340 a, 340 b may create a diamond pattern.Perimeters 344 may be aligned with frame members 326 of stent 312 suchthat centers 342 are overlapping cells 328. Protrusions 340 a, 340 b mayhave a half diamond or half cell shape defined in part by perimeter 344.The shape of protrusions 340 a, 340 b may be referred to as a horseshoeshape.

Protrusions 340 a, 340 b and their associated centers 342 and perimeters344 may provide multiple rows of sealing interfaces between sealingmember 314 and the native annulus. Each row 347 a, 347 b of protrusions340 a, 340 b may provide a separate sealing interface or plurality ofsealing interfaces with the native annulus to limit PVL. Otherembodiments are possible in which sealing member 314 includes three ormore rows of protrusions, wherein each row of protrusions includes aplurality of individual protrusions. The protrusions of adjacent rowsmay be offset circumferentially. Protrusions 340 a, 340 b may have anyshape and size to provide a desired number and arrangement ofprotrusions on a given sealing member.

FIG. 13 shows heart valve assembly 400 having stent 412, sealing member414, and valve 416. Stent 412 includes inflow and outflow end portions420, 422, interior 424, plurality of frame members 426, and plurality ofcells 428. Valve 416 may be connected to stent 412 with connectingmembers 437. Valve 416 may also be connected to stent 412 with stitching438.

Sealing member 414 includes base 439 and plurality of protrusions 440.Protrusions 440 each include center 442, perimeter 444, and stitching446. Base 439 of sealing member 414 is positioned within interior 424and arranged in contact with an interior surface of stent 412.Protrusions 440 extend radially outward through cells 428 to a locationoutside of stent 412. Sealing member 414 may be positioned entirelywithin stent 412 prior to deployment at an implantation site.Protrusions 440, or at least portions thereof, may automatically extendradially outward through cells 428 when heart valve assembly 400 isdeployed at the implantation site.

Sealing member 414 may be interposed between stent 412 and a portion ofvalve 416. At least portions of sealing member 414 (e.g., base 439) maybe positioned overlapping with valve 416. Base 439 of sealing member 414is shown in FIG. 14 arranged in contact with an inner surface of stent412. An inner surface of sealing member 414 (e.g., an inner surface ofbase 439) may be arranged in contact with an outward facing surface ofvalve 416.

Sealing member 414 and valve 416 may be directly connected together.Sealing member 414 and valve 416 may be connected to stent 412 at aplurality of common attachment locations. Alternatively, sealing member414 may be connected to stent 412 at different locations than wherevalve 416 is connected to stent 412.

Sealing member 414 may be secured to stent 412 using plurality ofattachment stitches 448, as shown in FIG. 13 and the cross-sectionalview of FIG. 14. Attachment stitches 448 may connect sealing member 414to frame members 426 of stent 412, as shown in FIG. 14. Attachmentstitches 448 may extend through both sealing member 414 and valve 416 toprovide a connection there between. In alternative embodiments, the sameattachment stitches 448 used to secure sealing member 414 and valve 416together may also wrap around portions of stent 412 to provide aconnection with stent 412.

FIG. 14 shows base 439 of sealing member 414 interposed between interiorsurfaces of frame members 426 and an exterior surface of valve 416.Stent 412 may radially expand sealing member 414 and valve 416 byapplying a pulling force in a radial outward direction when stent 412 isdeployed rather than pushing sealing member 414 radially outward as inother embodiments in which the sealing member is positioned entirelyoutside of stent 412. When stent 412 is collapsed (e.g., re-sheathed),stent 412 pushes sealing member 414 and valve 416 radially inward tocollapse sealing member 414 and valve 416. The pulling and pushingforces applied by stent 412 to sealing member 414 during expansion andcollapsing, respectively, is opposite to the forces applied by stent 12to sealing member 14 described above related to heart valve assembly 10.That is, stent 12 pushes sealing member 14 during expansion and pullssealing member 14 during collapsing.

In alternative embodiments (not shown), the sealing member may includeonly a number of protrusions that matches the number of leaflets of thevalve. Typically, an area around the valve assembly where greatest PVLoccurs is adjacent to the leaflets of the valve because of the highlevel of movement of the valve in that location and the associatedtension applied to the stent by the moving leaflets. Positioning aprotrusion directly adjacent to the leaflets of the valve in either aradially outward direction or distal direction may address many of thepotential PVL issues for a valve assembly. In one arrangement in whichthe valve includes three leaflets, the sealing member includes onlythree protrusions with each protrusion positioned in a cell of the stentjust distally of the leaflets.

FIGS. 15-18 show heart valve assembly 10 in combination with deliverysystem 50. Delivery system 50 is shown in FIGS. 15 and 16 includingcarrier tube 52, deployment member 54, and tip 56. Carrier tube 52includes interior 58 for containing heart valve assembly 10 duringdelivery to the implantation site (see FIG. 16). FIGS. 15-18 show heartvalve assembly 10 at various stages of deployment relative to deliverysystem 50. FIGS. 15 and 16 show heart valve assembly 10 compressed,collapsed and completely enclosed in carrier tube 52 prior todeployment. FIG. 17 shows heart valve assembly 10 partially deployed.FIG. 18 shows heart valve assembly 10 fully deployed and disconnectedfrom delivery system 50.

Prior to deployment, heart valve assembly 10 is collapsed or compressedand positioned entirely within carrier tube 52, as shown in FIGS. 15 and16. Sealing member 14 may overlap portions of stent 12 and valve 16 whenheart valve assembly 10 is compressed and held within carrier tube 52,as shown in FIG. 16. Sealing member 14 may be positioned betweenportions of stent 12 and/or valve 16 and an internal surface of interior58 of carrier tube 52. Deployment member 54 is connected to outflow endportion 22 of stent 12. Tip 56 extends through heart valve assembly 10and provides a tapered leading end for improved navigation throughvessels to the implantation site.

Deploying heart valve assembly 10 is initiated by retracting carriertube 52 in proximal direction P (relative to the operator), as shown inFIG. 17. Carrier tube 52 may be incrementally withdrawn in proximaldirection P and advanced in distal direction D to provide various stagesof partial deployment of heart valve assembly 10. A partial deploymentof heart valve assembly 10 includes any exposure of heart valve assembly10 outside of carrier tube 52 while maintaining connection of deploymentmember 54 to outflow end portion 22 of stent 12. FIG. 17 shows stent 12fully deployed from carrier tube 52 while remaining connected todeployment member 54. Heart valve assembly 10 may be re-sheathed, or atleast partially re-sheathed, back into carrier tube 52 from any full orpartial deployment of heart valve assembly 10. Re-sheathing is done byadvancing carrier tube 52 relative to heart valve assembly 10 in distaldirection D.

Stent 12, sealing member 14 and valve 16 typically self-expand into anexpanded, deployed position after being released from the constrainingforce applied by carrier tube 52. Sealing member 14 extends around anouter peripheral surface of stent 12 when heart valve assembly 10 movesinto the expanded, partially deployed position of FIG. 17. Protrusions40 of sealing member 14 create a sealed interface between heart valveassembly 10 and the native annulus (e.g., see FIG. 19).

FIG. 18 shows deployment member 54 disconnected from stent 12 so thatheart valve assembly 10 is fully deployed. Deployment member 54 mayinclude a plurality of actuatable fasteners or other connection featuresthat permit selective disconnection from stent 12. Once disconnectedfrom deployment member 54, outflow end portion 22 of stent 12 furtherexpands radially outward.

FIGS. 19 and 20 show heart valve assembly 10 and delivery system 50positioned within heart 60. Heart 60 is shown in FIGS. 19 and 20including aorta 62, left ventricle 64, and native annulus 66. Blood flowB is in a direction out of left ventricle 64 and into aorta 62 whenheart 60 pumps. Blood attempts to flow in an opposite direction backinto left ventricle 64 from aorta 62 when heart 60 relaxes.

Heart valve assembly 10 is initially deployed at native annulus 66 bypositioning tip 56 through native annulus and aligning sealing member 14of heart valve assembly 10 with native annulus 66. Heart valve assembly10 is partially deployed at native annulus 66 by withdrawing carriertube 52 is proximal direction P, as shown in FIG. 19. Stent 12 expandsradially outward to press protrusions and 40 sealing member 14 againstnative annulus 66 to form a seal therebetween. The operator may test forPVL by injecting a contrast agent in the area of heart valve assembly10.

The operator may choose to reposition heart valve assembly 10 to addressPVL issues observed using the ejected contrast agent. Re-sheathing isinitiated by advancing carrier tube 52 in distal direction D. Typically,the operator at least partially re-sheaths heart valve assembly 10enough to relieve the radially outward force applied by heart valveassembly 10 to native annulus 66. The operator then axially and/orrotationally repositions heart valve assembly 10 relative to nativeannulus 66. Heart valve assembly 10 is again partially redeployed byretracting carrier tube 52. Contrast agent is again ejected at nativeannulus 66 to test for PVL. If needed, the operator may again at leastpartially re-sheath and then reposition heart valve assembly 10 relativeto native annulus 66 followed by ejecting contrast agent to test forPVL.

Once the operator is satisfied with the position of heart valve assembly10 at native annulus 66 of heart 60, the operator may detach deploymentmember 54 from stent 12 to completely deploy heart valve assembly 10 atnative annulus 66 by detaching stent 12 from deployment member 54, asshown in FIG. 20. Delivery system 50 is then withdrawn in direction Pfrom the patient.

With heart valve assembly 10 completely deployed at native annulus 66,heart valve assembly 10 may operate to control blood flow between leftventricle 64 into aorta 62 and sealing member 14 provides resistance toPVL. Leaflets 35 of valve 16 may open in response to pressurized flow ofblood out of left ventricle 64 and into aorta 62. Leaflets 35 closeafter the pressurized flow of blood from left ventricle 64 stops toprevent back flow of blood from aorta 62 into left ventricle 64. Sealingmember 14 (e.g., protrusions 40) is pressed against native annulus 66 bystent 12 to create a seal that limits backflow of blood from aorta 62,around an outer perimeter of heart valve assembly 10, and into leftventricle 64. Sealing member 14 may provide a sealed interface betweenan outer surface of valve 16 (e.g., outer surface of valve cuff 36) andnative annulus 66 that limits PVL.

The sealing members disclosed herein may comprise various materials. Thematerial of the sealing member may generally be referred to as tissue.The sealing member may comprise, for example, a fabric such asPolytetrafluoroethylene (PTFE), Dacron, or Polyvinyl alcohol (PVA)threads, or other materials such as Gor-tex® and polymers such assilicone, saline, PVA, plastics, or living tissue such as fat. Thesealing member may include an inflatable material or have an inflatableconstruction configured to hold a volume of inflation fluid (e.g.,liquid saline or a gas). The sealing member may be inflatable after theheart valve assembly is deployed at an implantation site. The sealingmember may be deflatable prior to being re-sheathed as part ofrepositioning the heart valve assembly relative to an annulus. Thesealing member may include multiple materials. Further, some features ofthe sealing member, such as the protrusions, may have differentmaterials from other portions of the sealing member. For example, thesealing member may comprise a base layer comprising a first material,and the protrusions may extend radially outward from the base layer andcomprise a second material.

A number of methods may be associated with the heart valve assembliesand sealing members disclosed herein. One example method relates to amethod of forming a sealing member. The method includes pinching orfolding portions of the sealing member at a plurality of locationsaround a perimeter of the sealing member, and fixing the folded orpinched portion to provide a plurality of protrusions extending radiallyoutward from the sealing member. The protrusions may be fixed usingstitching. The stitching may extend around a perimeter of each of theprotrusions. The stitching may extend along a center line of theprotrusions. The stitching may include, for example, a ladder stitch, awhip stitch, reverse running stitches, or a crossing stitch that helpsfix a bulged shape for the protrusion. The protrusions may be contouredand include a cup shape, such as a hemispherical shape. Many othershapes and various sizes are possible for the protrusion. The sealingmember may have any arrangement or pattern of protrusions around itsperiphery. Depending on the type of material used in the sealing member,the protrusions alternatively may be heat set or formed using aparticular knitting pattern or material density in the sealing member.

Another example method relates to manufacturing a valve assembly. Themethod may include providing a stent, a valve, and a sealing member,wherein the stent has a self-expandable and collapsible construction andthe sealing member includes a plurality of protrusions. The valve may bemounted within the stent. The sealing member may be mounted to the stentwith the plurality of protrusions extending radially outward. Theprotrusions may extend through cells (e.g., between frame members) ofthe stent. The sealing member may be positioned on an exterior surfaceof the stent, or may be positioned along an interior surface of thestent with the protrusions extending through the stent. The sealingmember may overlap a portion of the valve, such as a base portion of thevalve spaced axially from leaflets of the valve. A plurality ofprotrusions may be arranged in rows or other patterns around an outerperiphery surface of the sealing member. The sealing member may besecured to the stent using, for example, stitching or other attachmentmeans. The sealing member may be connected to the stent in a way thatpermits self-expanding and collapsing of the stent, which occurs duringplacement and repositioning of the heart valve assembly at animplantation site.

Another method relates to deploying a heart valve assembly at animplantation site such as at the site of a native heart valve. Themethod may include providing the heart valve assembly with a stent, avalve, and a sealing member. The sealing member may include a pluralityof sealing protrusions. The protrusions may extend radially outward. Themethod may include positioning the heart valve assembly at theimplantation site with the sealing member aligned with an annulus. Theheart valve assembly is deployed at the implantation site and thesealing member provides a sealing interface between the heart valveassembly and the annulus. The protrusions may provide a sealing orcupping function between the heart valve assembly and the annulus thatlimits black flow of blood. A method of providing a sealed interfacebetween a heart valve assembly and an annulus at an implantation sitemay include similar method steps.

Another aspect of the present disclosure relates to a heart valveassembly that includes a heart valve, a self-expandable and collapsiblestent, and a sealing member. The stent includes an inflow end and anoutflow end and is configured to support the heart valve internally. Thesealing member is connected to and extends circumferentially around thestent. The sealing member includes a plurality of radially outwardextending protrusions comprising a fold of material of the sealingmember.

The plurality of radially outward extending protrusions may be equallyspaced apart around a circumference of the sealing member. The pluralityof radially outward extending protrusions may include first and secondaxially spaced apart rows of the radially outward extending protrusions.The plurality of radially outward extending protrusions may bepositioned at an inflow end of the stent. The plurality of radiallyoutward extending protrusions may be arranged in at least one rowextending around a circumference of the stent, wherein the at least onerow is arranged at an angle relative to a longitudinal axis of thestent.

At least a portion of the sealing member may be positioned on the stentat a location distal of the heart valve. The sealing member may includea stitch pattern to form the plurality of radially outward extendingprotrusions. Each of the plurality of radially outward extendingprotrusions may include a plurality of stitches. The sealing member mayinclude fabric. The sealing member may be mounted to a radially inwardfacing surface of the stent, and the plurality of radially outwardextending protrusions may extend through the stent. The sealing membermay be mounted to a radially outward facing surface of the stent. Thestent may include annular, sinus and aortic sections, and the sealingmember may be positioned at least partially along at least one of theannular and sinus sections. The sealing member may be connected to theheart valve. A central axis of the sealing member may be arranged at anangle relative to a longitudinal axis of the stent.

Another aspect of the present disclosure relates to a sealing member foruse with a valve assembly. The sealing member includes a base configuredfor attachment to a self-expandable and collapsible stent. The pluralityof protrusions are formed in a radially outward facing surface of thebase and configured to provide a sealed interface between the valveassembly and an annulus at an implantation site.

The plurality of protrusions may include a fold in the base. Theplurality of protrusions may include stitching. The sealing member mayfurther include stitching secured to the sealing member to maintain afolded shape of the plurality of protrusions. The plurality ofprotrusions may be arranged in at least one row extending around thebase.

Another aspect of the present disclosure relates to a method ofmanufacturing a valve assembly. The method includes providing a stent, avalve, and a sealing member. The stent has a self-expandable andcollapsible construction. The sealing member includes a plurality ofprotrusions. The method further includes mounting the valve within thestent, and mounting the sealing member to the stent with the pluralityof protrusions extending radially outward.

The method may also include forming the plurality of protrusions with apattern of stitches secured to the sealing member. Mounting the sealingmember to the stent may include positioning the sealing member withinthe stent. The method may also include arranging the plurality ofprotrusions in at least one row extending around a circumference of thesealing member.

As used in this specification and the appended claims, the term “engage”and “engagable” are also used broadly to mean interlock, mesh, orcontact between two devices. A “tube” is an elongated device with apassageway. The passageway may be enclosed or open (e.g., a trough). A“lumen” refers to any open space or cavity in a bodily organ, especiallyin a blood vessel. The words “including” and “having,” as used in thespecification, including the claims, have the same meaning as the word“comprising.”

The preceding description has been presented only to illustrate anddescribe exemplary embodiments of the invention. It is not intended tobe exhaustive or to limit the invention to any precise form disclosed.Many modifications and variations are possible in light of the aboveteaching. It is intended that the scope of the invention be defined bythe following claims.

What is claimed is:
 1. A heart valve assembly, comprising: a heartvalve; a self-expandable and collapsible stent comprising an inflow endand an outflow end and being configured to support the heart valveinternally; and a sealing member connected to and extendingcircumferentially around the stent, the sealing member including aplurality of radially outward extending protrusions comprising a fold ofmaterial of the sealing member.
 2. The heart valve assembly of claim 1,wherein the plurality of radially outward extending protrusions areequally spaced apart around a circumference of the sealing member. 3.The heart valve assembly of claim 1, wherein the plurality of radiallyoutward extending protrusions includes first and second axially spacedapart rows of the radially outward extending protrusions.
 4. The heartvalve assembly of claim 1, wherein the plurality of radially outwardextending protrusions are positioned at an inflow end of the stent. 5.The heart valve assembly of claim 1, wherein the plurality of radiallyoutward extending protrusions are arranged in at least one row extendingaround a circumference of the stent.
 6. The heart valve assembly ofclaim 1, wherein at least a portion of the sealing member is positionedon the stent at a location distal of the heart valve.
 7. The heart valveassembly of claim 6, wherein the sealing member includes a stitchpattern to form the plurality of radially outward extending protrusions.8. The heart valve assembly of claim 1, wherein each of the plurality ofradially outward extending protrusions includes a plurality of stitches.9. The heart valve assembly of claim 1, wherein the sealing membercomprises fabric.
 10. The heart valve assembly of claim 1, wherein thesealing member is mounted to a radially inward facing surface of thestent, and the plurality of radially outward extending protrusionsextend through the stent.
 11. The heart valve assembly of claim 1,wherein the sealing member is mounted to a radially outward facingsurface of the stent.
 12. The heart valve assembly of claim 1, whereinthe stent includes annular, sinus and aortic sections, and the sealingmember is positioned at least partially along at least one of theannular and sinus sections.
 13. The heart valve assembly of claim 1,wherein the sealing member is connected to the heart valve.
 14. Theheart valve assembly of claim 1, wherein a central axis of the sealingmember is arranged at an angle relative to a longitudinal axis of thestent.
 15. A sealing member for use with a valve assembly, comprising: abase configured for attachment to a self-expandable and collapsiblestent; and a plurality of protrusions formed in a radially outwardfacing surface of the base and configured to provide a sealed interfacebetween the valve assembly and a native annulus at an implantation site.16. The sealing member of claim 15, wherein the plurality of protrusionsinclude a fold in the base.
 17. The sealing member of claim 15, whereinthe plurality of protrusions include stitching.
 18. The sealing memberof claim 15, further comprising: stitching secured to the sealing memberto maintain a folded shape of the plurality of protrusions.
 19. Thesealing member of claim 15, wherein the plurality of protrusions arearranged in at least one row extending around the base.
 20. A method ofmanufacturing a valve assembly, comprising: providing a stent, a valve,and a sealing member, the stent having a self-expandable and collapsibleconstruction, the sealing member including a plurality of protrusions;mounting the valve within the stent; and mounting the sealing member tothe stent with the plurality of protrusions extending radially outward.21. The method of claim 20, further comprising: forming the plurality ofprotrusions with a pattern of stitches secured to the sealing member.22. The method of claim 20, wherein mounting the sealing member to thestent includes positioning the sealing member within the stent.
 23. Themethod of claim 20, further comprising: arranging the plurality ofprotrusions in at least one row extending around a circumference of thesealing member.